DE102020117704A1 - Refrigeration system of a vehicle air conditioning system with a refrigerant circuit and a fluid heating circuit - Google Patents

Abstract

The invention relates to a vehicle air conditioning system with a refrigeration system (1), a vehicle air conditioning system with a refrigerant circuit (1.1), comprising - an evaporator (12) for operating the refrigeration system, - a refrigerant compressor (2) for compressing a refrigerant, - at least one heat exchanger (3, 4 ), with which heat from the ambient air (L1) of the vehicle and/or waste heat from at least one electrical component (5) of the vehicle is transferred to the refrigerant of the refrigerant circuit (1) in order to carry out a heat pump function, - a the at least one heat exchanger (3, 4) associated expansion element (3.1, 4.1), and- a heat exchanger (6) arranged in an air conditioning unit (1.10) and thermally coupled to the refrigerant circuit (1) and representing a heat source for transferring the heat from the ambient air (L1) and/or the waste heat of the electrical component (5) to the air conditioner (1.10) supplied supply air flow (L2).Erfindungsgemä ß it is provided that- a fluid heating circuit (1.2) with a fluid-air heat exchanger (7), a high-voltage heating element (8) and a fluid pump (9) is provided,- the fluid-air heat exchanger ( 7) is arranged in the air conditioning unit (1.10), and the fluid-air heat exchanger (7) is connected downstream of the evaporator (12) on the air side.

Description

The invention relates to a refrigeration system of a vehicle air conditioning system with a refrigerant circuit according to the preamble of patent claim 1.

Such a refrigeration system is from the DE 10 2017 202 680 A1 known. The refrigerant circuit of this refrigeration system is equipped with a heat pump function, with which ambient heat and/or waste heat from an electrical component of the vehicle is transferred to the refrigerant circuit and from there by means of a heating heat exchanger (also known as a heating register) either directly or indirectly to an air flow routed into a passenger compartment . This heating heat exchanger is located together with an electrical high-voltage heating element in an air conditioning unit and is downstream of the heating heat exchanger on the air side. This high-voltage heating element is used to provide additional heating energy for the passenger compartment for comfortable heating when ambient temperatures are low.

the DE 10 2015 206 928 A1 describes a heating device for a vehicle with a heating circuit, which is operated with a liquid as the heat transfer medium and a heating element for heating the heat transfer medium, a heat exchanger for transferring the heat from the heat transfer medium to a supply air flow flowing into the vehicle interior and an electric pump for circulating the heat exchanger in the interior Has heating circuit, wherein the heating element is integrated in such a way in a pump chamber of the pump that the heating element is flowed directly from the heat carrier. Such a heating device is intended for use in an electric vehicle and is therefore independent of an internal combustion engine.

A heating system for a hybrid vehicle includes according to DE 10 2015 222 806 A1 a cooling circuit provided for cooling an internal combustion engine with a cooling circuit in which the internal combustion engine is arranged, and a heating circuit which includes a heating heat exchanger, an electric heating element for interior heating and a heating circuit pump. The cooling circuit can be fluidly connected to the heating circuit.

Finally describes the EP 1 013 487 B1 an air conditioning system for a vehicle with an internal combustion engine, which is arranged in a cooling circuit for cooling. A heating circuit can be connected in parallel with the cooling circuit and has a heating heat exchanger arranged in an air conditioning unit.

The invention is based on the object of creating a refrigeration system of the type mentioned at the outset with improved properties, in particular with a high degree of homogeneity with regard to the temperature distribution of the air flow flowing into the vehicle interior and a high heat storage capacity.

This problem is solved by a refrigeration system with the features of patent claim 1.

• - einen Verdampfer zur Durchführung eines Kälteanlagenbetriebs,
• - einen Kältemittelverdichter zum Verdichten eines Kältemittels,
• - mindestens einen Wärmeübertrager, mit welchem zur Durchführung einer Wärmepumpenfunktion Wärme aus der Umgebungsluft des Fahrzeugs und/ oder Abwärme wenigstens einer elektrischen Komponente des Fahrzeugs auf das Kältemittel des Kältemittelkreislaufs übertragen wird,
• - ein dem mindestens einen Wärmeübertrager zugeordnetes Expansionsorgan, und
• - einen in einem Klimagerät angeordneten und mit dem Kältemittelkreislauf thermisch gekoppelten und eine Wärmequelle darstellenden Wärmeübertrager zur Übertragung der Wärme aus der Umgebungsluft und/ oder der Abwärme der elektrischen Komponente auf einen dem Klimagerät zugeführten Zuluftstrom.

Such a refrigeration system of a vehicle air conditioning system with a refrigerant circuit includes:

• - an evaporator for performing a refrigeration system operation,
• - a refrigerant compressor for compressing a refrigerant,
• - at least one heat exchanger, with which heat from the ambient air of the vehicle and/or waste heat from at least one electrical component of the vehicle is transferred to the refrigerant of the refrigerant circuit in order to carry out a heat pump function,
• - an expansion element assigned to the at least one heat exchanger, and
• - A heat exchanger arranged in an air conditioner and thermally coupled to the refrigerant circuit and representing a heat source for transferring the heat from the ambient air and/or the waste heat from the electrical component to an inlet air flow fed to the air conditioner.

• - ein Fluid-Heizkreis mit einem Fluid-Luft-Wärmeübertrager, einem Hochvolt-Heizelement und einer Fluid-Pumpe vorgesehen ist,
• - der Fluid-Luft-Wärmeübertrager in dem Klimagerät angeordnet ist und
• - der Fluid-Luft-Wärmeübertrager dem Verdampfer luftseitig nachgeschaltet ist.

According to the invention it is provided that

• - a fluid heating circuit with a fluid-air heat exchanger, a high-voltage heating element and a fluid pump is provided,
• - The fluid-air heat exchanger is arranged in the air conditioner and
• - the fluid-air heat exchanger is downstream of the evaporator on the air side.

In this refrigeration system, instead of an electric air heater known from the prior art, an indirect heating system is provided, which consists of a fluid heating circuit with at least one fluid-air heat exchanger, a high-voltage heating element and a fluid pump and can be constructed in a compact manner. With the high-voltage heating element, the fluid, e.g. water-glycol mixture of the fluid heating circuit is heated, which in turn gives off the heat by means of the fluid-air heat exchanger to the supply air flow flowing into the vehicle interior. In addition to the main components, there are usually the components ten connecting and fluid-carrying line elements and, if necessary, provide for the (temperature) sensors required for operation.

By using such a fluid-air heat exchanger, the temperature distribution in the heated supply air flow is much more homogeneous than with an air heater, since its fluid-side flow concept through the heat-carrying medium can be easily designed to meet the applicable or to be presented requirements. In addition, compared to the use of such an air heater, a higher heat storage capacity is achieved due to the use of fluid, such as water appear.

Another advantage of the refrigeration system according to the invention lies in the combination of the refrigerant circuit with a fluid heating circuit, which is not thermally coupled to the refrigerant circuit, i. H. the fluid heating circuit has no interfaces to other systems, such as the superstructures in internal combustion engine concepts and its coupling to the fluid flows of the internal combustion engine, so it is self-contained. This means that the functions of the refrigerant circuit are retained with a heat pump function, i. H. the supply air flow flowing into the vehicle interior is cooled by an evaporator, dehumidified and/or preheated or heated via the heat exchanger working as a heat source or reheated or heated by means of the heat exchanger working as a heat source.

For the sake of completeness, it should be mentioned that the fluid-air heating circuit should be connected to an expansion tank if required.

It is particularly advantageous if, according to a further development, the fluid-air heat exchanger is connected on the air side downstream of the heat exchanger operating as a heat source, also known as a heating register. This achieves high efficiency of the refrigeration system.

Alternatively, it is also possible to connect the fluid-air heat exchanger upstream of the heat exchanger working as a heat source on the air side. This offers the advantage that the circulating medium can be cooled via the directly upstream evaporator and thus the possibility of cold storage in the fluid circuit can be presented. In this way, in the heating mode, the high pressure can be increased in a targeted and dynamic manner in heat pump operation or in reheat operation, thereby supporting the heating process.

According to a particularly advantageous development of the invention, it is provided that the fluid heating circuit includes a thermal energy store for storing heat and/or for storing cold.

Such a thermal energy store can be used as a heat store or as a cold store in the fluid heating circuit.

If this thermal energy store is used as a heat store, thermal energy is first stored and used at a later point in time to heat the supply air flow flowing into the vehicle interior. The advantage of using such a heat accumulator is that it compensates for the cooling dynamics of the fluid in the fluid heating circuit if temporary losses in the provision of heat for airflow heating are to be expected after or possibly also during standing phases or switching processes. These short-term heating deficits can be intercepted and compensated for by a heat storage function.

In the other case, the thermal energy store can be used as a cold store for an additional function in summer, i.e. when cooled fluid flows through the cold store and the cold energy stored in this way can be used at a later point in time to cool the supply air flow flowing into the vehicle interior. Short-term cold deficits can be intercepted and compensated for by a cold storage function. In this case, of course, the high-voltage heating element is switched off.

The arrangement of the respective heat exchangers in the air conditioning unit downstream of the evaporator, which can be more or less suitable for the implementation of the respective storage function depending on the application, is decisive for the representation of a cold or heat storage function.

In a thermal energy store, phase change materials (PCM, Phase Change Materials) are primarily used due to their high power density.

Alternatively, the storage function can simply be represented by an increased water volume.

As an alternative to using a thermal energy store or in addition to such a thermal energy store, according to a further preferred embodiment of the invention, the fluid Air heat exchanger designed as a heat accumulator.

The advantage of using such a storage heat exchanger is also that it compensates for the cooling dynamics of the air flow if temporary losses in the provision of cold for cooling the air flow are to be expected after or possibly also during standing phases or switching processes. These short-term cooling deficits can be intercepted and compensated for by a cold storage function.

Finally, according to a last advantageous development of the invention, provision is made for an electrical heating element to be arranged downstream of the fluid/air heat exchanger on the air side. The heating element is preferably designed on a low-voltage basis as a low-voltage heating element.

The use of such a low-voltage heating element is popular in summer when there is only a low heating requirement for the vehicle interior. In winter, this can increase the overall heat output of the system. However, the primary goal is to use the reheat mode in summer and the heat pump mode of the refrigeration system in winter to achieve the required air conditioning goals.

• 1 eine schematische Darstellung einer Kälteanlage mit einem Kältemittelkreislauf mit Wärmepumpenfunktion und einem Fluid-Heizkreis als erstes Ausführungsbeispiel der Erfindung, und
• 2 eine schematische Darstellung einer Kälteanlage mit einem Kältemittelkreislauf mit Wärmepumpenfunktion und einem Fluid-Heizkreis als zweites Ausführungsbeispiel der Erfindung.

Further advantages, features and details of the invention result from the following description of preferred embodiments and from the drawings. show:

• 1 a schematic representation of a refrigeration system with a refrigerant circuit with heat pump function and a fluid heating circuit as a first embodiment of the invention, and
• 2 a schematic representation of a refrigeration system with a refrigerant circuit with heat pump function and a fluid heating circuit as a second embodiment of the invention.

the 1 shows a refrigeration system 1 of a vehicle air conditioning system of a vehicle with a refrigerant circuit 1.1, in which only the components and lines required for a heat pump function are shown, and a fluid heating circuit 1.2.

To 1 the refrigerant circuit 1.1 comprises a refrigerant compressor 2, a second heat exchanger 6 (also called a heating coil) working as a heat source, a first heat exchanger 3 working as a heat source (condenser/gas cooler) or also as a heat sink (heat pump evaporator) with a Expansion valve formed expansion element 3.1, wherein these components are flowed through by the refrigerant compressed by means of the refrigerant compressor 2 refrigerant in the order listed. After flowing through the second heat exchanger 6, the compressed refrigerant is expanded by means of the expansion element 3.1 into the first heat exchanger 3 in order to absorb heat from the ambient air L1 of the vehicle. This implements a heat pump function in that the heat absorbed in the heat pump evaporator from the surroundings of the vehicle is transferred by means of the second heat exchanger 6 to an inlet air flow L2 flowing into the vehicle interior.

Instead of the ambient air L1 as a heat source for the heat pump, at least one electrical component 5, e.g. an electric drive motor of the vehicle, a high-voltage battery, power electronics, etc. can be used as a heat source instead of this heat source or in addition, as shown in 1 is evident. For this purpose, for example, a chiller is provided as a heat exchanger 4, which thermally couples the refrigerant circuit 1.1 to a coolant circuit 1.3 of the heat exchanger 4, in which the electrical component 5 is arranged. The coolant of the coolant circuit 1.3 is heated with the waste heat from the electrical component 5 and transferred to the coolant circuit 1.1 via the heat exchanger 4 . If the heat exchanger 4 is integrated into the refrigerant circuit 1.1, the refrigerant compressed by the refrigerant compressor 2 is expanded into the heat exchanger 4 after flowing through the second heat exchanger 6 by means of an expansion element 4.1 provided separately for the heat exchanger 4.

In an air conditioner 1.10 of the refrigerant circuit 1.1, in addition to an evaporator 12 required for AC operation of the refrigerant circuit 1.1 with an associated expansion element 12.1 designed as an expansion valve, the second heat exchanger 6 and a fluid-air heat exchanger 7 are arranged. This fluid-air heat exchanger 7 is downstream of the second heat exchanger 6 on the air side, so that an inlet air flow L2 to be supplied to the vehicle interior is first supplied to the vehicle interior via the evaporator 12, then via the second heat exchanger 6 and finally via the fluid-air heat exchanger 7.

The fluid-air heat exchanger 7 is part of a fluid heating circuit 1.2, in which fluid, for example a water-glycol mixture, is used as the heat carrier. In addition to this fluid-air heat exchanger 7, the fluid heating circuit 1.2 includes a high-voltage heating element 8 and a fluid pump 9. With this fluid pump 9, the fluid in the Fluid heating circuit circulated 1.2. If necessary, the fluid heating circuit 1.2 is connected to an expansion tank, not shown.

The high-voltage heating element 8 is designed as a high-voltage PTC heater and is operated at a comparatively high voltage of at least 50 V, generally between 200 V and 450 V at a rated voltage of 400 V. Other voltage levels up to 1000V can occur.

In accordance with the refrigerant circuit 1.1 1 a heating operation is carried out by means of the heat pump function, in that the ambient heat absorbed by the first heat exchanger 3 and/or the waste heat of the electrical component 5 absorbed by the heat exchanger 4 is transferred to the supply air flow L 2 by means of the second heat exchanger 6 operating as a heat source.

If the heating requirement is greater than the heat energy provided by the heat pump function, the fluid of the fluid heating circuit 1.2 is heated by the high-voltage heating element 8 and the heat energy still missing to meet the heating requirement for the interior is used by the fluid/air heat exchanger 7 transfer the supply air flow L2 before it can flow into the vehicle interior.

In the fluid heating circuit 1.2 can according 1 In addition, a thermal energy store 10 can be added, which can be used either as a heat store or as a cold store.

If this thermal energy store 10 is used as a heat store, thermal energy is first stored and used at a later point in time to heat the supply air flow flowing into the vehicle interior. To charge the thermal energy store 10 with thermal energy, heat is introduced into the fluid by means of the high-voltage heating element 8, or when the high-voltage heating element 8 is inactive or working at reduced power, the waste heat from the second heat exchanger 6 can be used to transfer heat to the heating fluid and thus charge the heat store be used.

In addition or as an alternative, it is also possible to design the fluid/air heat exchanger 7 as a heat accumulator. For this purpose, for example, phase change material is integrated in such a heat exchanger. With such a fluid-air heat exchanger 7 designed as a heat accumulator, it is achieved that in situations where the heat pump is switched off for a short time, e.g. feel a loss of comfort.

Next, a low-voltage heating element 11 can be arranged in the air conditioner 1.10. In particular for AC operation in the summer, this low-voltage heating element 11 can be used to heat the supply air flow L2 when there is a low heating requirement. In this case, the thermal energy store 10 is used as a cold store. Post-heating by means of the heat exchanger 6 is omitted here. In addition, the low-voltage heating element 11 can also be used to support the heating process in cold ambient conditions.

The embodiment according to 2 shows a refrigeration system 1 with a refrigerant circuit 1.1 and a fluid heating circuit 1.2, the difference to the refrigeration system 1 according to 1 is that the positions of the second heat exchanger 6 and the fluid-air heat exchanger 7 are swapped in the air conditioner 1.10. The supply air flow L2 is thus first routed after the evaporator 12 via the fluid-air heat exchanger 7 and only then via the second heat exchanger 6 before it optionally flows via the low-voltage heating element 11 or directly into the vehicle interior.

In this refrigeration system 1, too, the fluid-air heat exchanger 7 is only operated when a general heating deficit occurs at the heating heat exchanger 6, which a heat pump or heat pump reheat operation cannot cover or compensate for. If there is excess heat in the refrigerant circuit 1.1, the heat output in the fluid-to-air heat exchanger 7 is gradually reduced by reducing the power on the electric high-voltage heating element 8 and/or the speed of the fluid pump 9 is reduced until reheat operation takes place exclusively via the second heat exchanger 6 .

With this arrangement of the fluid-air heat exchanger 7 in the air conditioning unit 1.10, post-heating takes place in a reheat mode by means of the second heat exchanger 6, while if necessary a thermal energy store 10 used as a cold store is charged with cold energy by means of the evaporator 12.

A low-voltage heating element 11 can also be provided on the air side downstream of the second heat exchanger 6 with this modified arrangement of the second heat exchanger 6 .

The refrigeration system 1 can be used in addition to the evaporator 12, for example, as a front evaporator is formed, have a further evaporator, e.g. as a rear evaporator.

A component working as a heat source can be connected downstream of such a further evaporator for a post-heating or heating process. Either the heating or post-heating is carried out purely electrically, but with a reduced-power and therefore, in relation to the temperature distribution, less subject to scattering electric heat source, or for this additional evaporator also a further fluid heating circuit corresponding to the fluid heating circuit 1.2 is used.

A further possibility is to expand the fluid heating circuit 1.2 used for the evaporator 12 in such a way that, in addition to the fluid-air heat exchanger 7, another fluid-air heat exchanger is used for the additional evaporator, which is either the fluid-air Heat exchanger 7 is connected in parallel or in series.

In the case of a parallel connection, the fluid flow can be activated, deactivated or regulated if necessary by taking into account valves on the fluid side.

In the case of a series connection, the fluid flow can be activated, deactivated or regulated, if necessary, by taking into account valves on the fluid side and possibly at least one bypass line. The arrangement of the further fluid-air heat exchanger is preferably such that first the fluid-air heat exchanger 7 downstream of the evaporator 12 and then the further fluid-air heat exchanger downstream of the further evaporator are flowed through by the heat transfer medium.

Reference List

1

refrigeration system

1.1

Refrigerant circulation

1.10

air conditioner

1.2

Fluid heating circuit

1.3

coolant circuit

2

refrigerant compressor

3

heat exchanger

3.1

expansion organ

4

heat exchanger

4.1

expansion organ

5

electrical component

6

Heat exchanger as heat source

7

Fluid-air heat exchanger

8th

high-voltage heating element

9

fluid pump

10

thermal energy storage

11

Low voltage heating element

12

Evaporator

12.1

expansion organ

L1

ambient airflow

L2

supply airflow

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 102017202680 A1 [0002]
• DE 102015206928 A1 [0003]
• DE 102015222806 A1 [0004]
• EP 1013487 B1 [0005]

Claims (6)

Refrigeration system (1) of a vehicle air conditioning system with a refrigerant circuit (1.1), comprising - an evaporator (12) for operating the refrigeration system, - a refrigerant compressor (2) for compressing a refrigerant, - at least one heat exchanger (3, 4) with which to conduct a heat pump function, heat from the ambient air (L1) of the vehicle and/or waste heat from at least one electrical component (5) of the vehicle is transferred to the refrigerant of the refrigerant circuit (1), - an expansion element (3.1 , 4.1), and - a heat exchanger (6) arranged in an air conditioning unit (1.10) and thermally coupled to the refrigerant circuit (1) and representing a heat source for transferring the heat from the ambient air (L1) and/or the waste heat from the electrical component ( 5) on a supply air flow (L2) supplied to the air conditioning unit (1.10), characterized in that - a fluid heating circuit (1.2) is provided with a fluid-air heat exchanger (7), a high-voltage heating element (8) and a fluid pump (9), - the fluid-air heat exchanger (7) is arranged in the air conditioning unit (1.10), and - the fluid-air heat exchanger (7) is downstream of the evaporator (12) on the air side. Refrigeration system (1) after claim 1 , characterized in that the fluid-air heat exchanger (7) is downstream of the heat exchanger (6) operating as a heat source on the air side. Refrigeration system (1) after claim 1 , characterized in that the fluid-air heat exchanger (7) is upstream of the heat exchanger (6) operating as a heat source on the air side. Refrigeration system (1) according to one of the preceding claims, characterized in that the fluid heating circuit (1.2) comprises a thermal energy store (10) for storing heat and/or for storing cold. Refrigeration system (1) according to one of the preceding claims, characterized in that the fluid-air heat exchanger (7) is designed as a heat accumulator. Refrigeration system (1) according to one of the preceding claims, characterized in that an electric heating element (11) is arranged downstream of the fluid-air heat exchanger (7) on the air side.

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